Sphingolipids in Disease

Handbook of Experimental Pharmacology 216 Erich Gulbins Irina Petrache Editors Sphingolipids in Disease

Handbook of Experimental Pharmacology Volume 216 Editor-in-Chief F.B. Hofmann, München Editorial Board J.E. Barrett, Philadelphia J. Buckingham, Uxbridge V.M. Flockerzi, Homburg D. Ganten, Berlin P. Geppetti, Florence M.C. Michel, Ingelheim P. Moore, Singapore C.P. Page, London W. Rosenthal, Berlin For further volumes: http://www.springer.com/series/164

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Erich Gulbins Irina Petrache Editors Sphingolipids in Disease

Editors Erich Gulbins Department of Molecular Biology University of Duisburg-Essen Essen Germany Irina Petrache Division of Pulmonary, Allergy, Critical Care and Occupational Medicine Department of Medicine Indiana University School of Medicine Indianapolis, IN, USA ISSN 0171-2004 ISSN 1865-0325 (electronic) ISBN 978-3-7091-1510-7 ISBN 978-3-7091-1511-4 (ebook) DOI 10.1007/978-3-7091-1511-4 Springer Wien Heidelberg New York Dordrecht London Library of Congress Control Number: 2013935589 # Springer-Verlag Wien 2013 This work is subject to copyright. All rights are reserved by the Publisher, whether the whole or part of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission or information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed. Exempted from this legal reservation are brief excerpts in connection with reviews or scholarly analysis or material supplied specifically for the purpose of being entered and executed on a computer system, for exclusive use by the purchaser of the work. Duplication of this publication or parts thereof is permitted only under the provisions of the Copyright Law of the Publisher s location, in its current version, and permission for use must always be obtained from Springer. Permissions for use may be obtained through RightsLink at the Copyright Clearance Center. Violations are liable to prosecution under the respective Copyright Law. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publication does not imply, even in the absence of a specific statement, that such names are exempt from the relevant protective laws and regulations and therefore free for general use. While the advice and information in this book are believed to be true and accurate at the date of publication, neither the authors nor the editors nor the publisher can accept any legal responsibility for any errors or omissions that may be made. The publisher makes no warranty, express or implied, with respect to the material contained herein. Printed on acid-free paper Springer is part of Springer Science+Business Media (www.springer.com)

Preface Until the late 1980s, sphingolipids were believed to represent structural components of the plasma membrane, whose function was to provide a protective barrier to the cell. This picture dramatically changed within the last years. Sphingolipids are now recognized signals for fundamental cellular processes such as proliferation, survival, cell death, adhesion, migration, angiogenesis, and embryogenesis. The explosion of knowledge regarding sphingolipids was facilitated by biochemical studies of their signaling properties, the cloning of enzymes of the sphingolipid metabolism, development of genetic models for determining their physiologic roles, and the establishment of biochemical, biophysical, and optical methods for their detection and quantitation. The next step in the evolution of sphingolipids will be the transfer of basic insights into the biochemistry and cell biology of human disease. The recent success of the sphingolipid drug, Fingolimod, a sphingosine 1-phosphate agonist, which rapidly became a therapy for multiple sclerosis, exemplifies the potential of targeting sphingolipids for the treatment of human disorders. The aim of our two volumes in this series Sphingolipids: Basic Science and Drug Development and Sphingolipids in Disease is to define the state of the art of sphingolipid biology and to present preclinical developments and early clinical applications of this fascinating class of lipids. Essen, Germany Indianapolis, IN, USA Erich Gulbins Irina Petrache v

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Contents Part I Sphingolipids in Cancer Sphingosine Kinase/Sphingosine 1-Phosphate Signaling in Cancer Therapeutics and Drug Resistance... 3 Shanmugam Panneer Selvam and Besim Ogretmen Using ASMase Knockout Mice to Model Human Diseases... 29 Guoqiang Hua and Richard Kolesnick New Perspectives on the Role of Sphingosine 1-Phosphate in Cancer... 55 Susan Pyne and Nigel J. Pyne Sphingolipids and Response to Chemotherapy... 73 Marie-Thérèse Dimanche-Boitrel and Amélie Rebillard Lung Cancer and Lung Injury: The Dual Role of Ceramide... 93 Tzipora Goldkorn, Samuel Chung, and Simone Filosto Sphingolipids Role in Radiotherapy for Prostate Cancer... 115 Carla Hajj and Adriana Haimovitz-Friedman Part II Sphingolipids in Cardio-Reno-vascular Diseases Sphingolipid Metabolism and Atherosclerosis... 133 Xian-Cheng Jiang and Jing Liu Cardiovascular Effects of Sphingosine-1-Phosphate (S1P)... 147 Bodo Levkau Cross Talk Between Ceramide and Redox Signaling: Implications for Endothelial Dysfunction and Renal Disease... 171 Pin-Lan Li and Yang Zhang vii

viii Contents Part III Sphingolipids in Inflammation, Infection and Lung Diseases Sphingolipids in Lung Endothelial Biology and Regulation of Vascular Integrity... 201 Taimur Abbasi and Joe G.N. Garcia Sphingolipids in Acute Lung Injury... 227 Stefan Uhlig and Yang Yang The Involvement of Sphingolipids in Chronic Obstructive Pulmonary Diseases... 247 Irina Petrache and Daniela N. Petrusca Ceramide in Cystic Fibrosis... 265 Heike Grassmé, Joachim Riethmüller, and Erich Gulbins Regulation of the Sphingosine Kinase/Sphingosine 1-Phosphate Pathway... 275 K. Alexa Orr Gandy and Lina M. Obeid Bacterial Infections and Ceramide... 305 Heike Grassmé and Katrin Anne Becker Viral Infections and Sphingolipids... 321 Jürgen Schneider-Schaulies and Sibylle Schneider-Schaulies Ceramide in Plasma Membrane Repair... 341 Annette Draeger and Eduard B. Babiychuk Sphingolipids and Inflammatory Diseases of the Skin... 355 Burkhard Kleuser and Lukasz Japtok Sphingolipids in Obesity, Type 2 Diabetes, and Metabolic Disease... 373 S.B. Russo, J.S. Ross, and L.A. Cowart Part IV Sphingolipids in Neuro-psychiatry and Muscle Diseases Neuronal Forms of Gaucher Disease... 405 Einat B. Vitner and Anthony H. Futerman Sphingolipids in Neuroinflammation... 421 Laura Davies, Klaus Fassbender, and Silke Walter Sphingolipids in Psychiatric Disorders and Pain Syndromes... 431 C. Mühle, M. Reichel, E. Gulbins, and J. Kornhuber Role of Sphingosine 1-Phosphate in Skeletal Muscle Cell Biology... 457 Paola Bruni and Chiara Donati Index... 469

Part I Sphingolipids in Cancer

Sphingosine Kinase/Sphingosine 1-Phosphate Signaling in Cancer Therapeutics and Drug Resistance Shanmugam Panneer Selvam and Besim Ogretmen Contents 1 Introduction... 4 2 Sphingolipid Metabolism... 4 3 Ceramide/S1P Rheostat in Cancer... 5 4 S1P Signaling... 8 5 Roles of SK in Cancer Pathogenesis... 9 5.1 SK1 and Cancer... 9 5.2 SK2 and Cancer... 11 6 Role of S1P in Autophagy... 12 7 SK1/S1P Signaling in Drug Resistance... 13 8 SK2 and Drug Resistance... 15 9 S1P/S1PR2 Signaling in Cancer and Drug Resistance... 15 10 SK/S1P-Mediated Anticancer Therapeutics... 16 11 Conclusion and Future Perspectives... 19 References... 19 Abstract In this chapter, roles of bioactive sphingolipids, specifically sphingosine kinase 1 (SK1) and 2 (SK2) and their product sphingosine 1-phosphate (S1P) will be reviewed with respect to regulation of cancer growth, metastasis, chemotherapeutics, and drug resistance. Sphingolipids are known to be key bioeffector molecules that regulate cancer proliferation, angiogenesis, and cell death. Sphingolipid molecules such as ceramide and S1P have been shown to control cancer cell death and proliferation, respectively. Roles of S1P have been described with respect to their intracellular and extracellular pro-survival and drug resistance S.P. Selvam B. Ogretmen (*) Department of Biochemistry and Molecular Biology, Medical University of South Carolina, 86, Jonathan Lucas Street, Room 512A, Charleston, SC 29425, USA Hollings Cancer Center, Medical University of South Carolina, 86, Jonathan Lucas Street, Room 512A, Charleston, SC 29425, USA e-mail: ogretmen@musc.edu E. Gulbins and I. Petrache (eds.), Sphingolipids in Disease, Handbook of Experimental Pharmacology 216, DOI 10.1007/978-3-7091-1511-4_1, # Springer-Verlag Wien 2013 3

4 S.P. Selvam and B. Ogretmen functions mostly through S1P receptor (S1PR1-5) engagement. Identification of novel intracellular SK/S1P targets has broadened the existing complex regulatory roles of bioactive sphingolipids in cancer pathogenesis and therapeutics. Thus, deciphering the biochemical and molecular regulation of SK/S1P/S1PR signaling could permit development of novel therapeutic interventions to improve cancer therapy and/or overcome drug resistance. Keywords SK1 SK2 S1P S1PR Ceramide Cancer and Drug resistance Anti-Cancer therapeutics 1 Introduction Sphingolipids are structural and functional components of biological membranes (Ogretmen and Hannun 2004; Ponnusamy et al. 2010), which contribute to maintenance of membrane fluidity and subdomain structure. They are also implicated in bioeffector roles in cancer pathogenesis (Hannun and Obeid 2008; Ogretmen and Hannun 2004). Bioactive sphingolipids such as ceramide, sphingosine, and S1P are important in cell death pathways (apoptosis, necrosis, autophagy, anoikis), cancer proliferation, migration, inflammation, and drug resistance (Hannun and Obeid 2008; Ogretmen and Hannun 2004; Ponnusamy et al. 2010; Saddoughi et al. 2008). This chapter will focus on the roles of SK/S1P/S1PR signaling in cancer cell growth, therapeutics, drug resistance, and metastasis. 2 Sphingolipid Metabolism The de novo sphingolipid synthesis pathway (Fig. 1) begins with the condensation of serine and palmitoyl-coa catalyzed by serine palmitoyl transferase (SPT) (Dolgachev et al. 2004; Reynolds et al. 2004) leading to 3-ketosphinganine generation, which is rapidly reduced to dihydrosphingosine. Dihydrosphingosine is then N-acylated by a family of six dihydroceramide synthases (CerS1-6, also known as longevity associated gene, LAG, homologues, LASS1-6), which show preference for varying fatty acyl chain length specificity to synthesize dihydroceramide (Futerman and Hannun 2004). Then, a double bond is introduced between carbons 4 and 5 of the sphingosine backbone to generate ceramide (Kraveka et al. 2007; Michel et al. 1997). Ceramide is at the center of the sphingolipid metabolism, displaying mainly antiproliferative and pro-apoptotic roles (Ogretmen and Hannun 2004; Ponnusamy et al. 2010). Ceramide can be deacylated by ceramidases to generate sphingosine, which is rapidly phosphorylated by SK1 and SK2 to generate S1P, a pleiotropic lipid elucidating pro-survival, anti-apoptotic, metastatic, and/or chemoresistance functions in various cancers (Spiegel and Milstien 2003). S1P can be dephosphorylated by two S1P phosphatases (S1PP1 and S1PP2) in a reversible reaction to generate sphingosine (Mandala 2001; Mao et al. 1999; Spiegel and Milstien 2003), or S1P can be irreversibly cleaved by S1P lyase to form ethanolamine-1-phosphate and hexadecenal (Ikeda et al. 2004). Recently, S1P and

Sphingosine Kinase/Sphingosine 1-Phosphate Signaling in Cancer Therapeutics... 5 Serine + Palmitoyl CoA SPT 3-Ketosphinganine Sphinganine Dihydro CerS Glycosphingolipids Fatty acyl CoA dihydroceramide Desaturase H OH Glucosyl Ceramide CRS GCS Ceramide O NH OH SMS SMase Sphingomyelin Galactosylceramide CerS Ceramidase Sphingosine C1PP CK Ceramide-1-Phosphate Sulphatide S1PP S1P Sphingosine Kinase 1/2 S1P Lyase OH NH 2 Ethanolamine-1-Phosphate + Hexadecenal HO O O OH Fig. 1 De novo sphingolipid synthetic pathway. The initial step is the condensation of serine and palmitoyl-coa by serine palmitoyl transferase (SPT) followed by the action of ceramide synthases (CerS) and desaturase (DES) to generate ceramide. Ceramide is also generated by the degradation of sphingomyelin (SM) by sphingomyelinase (SMase) or by the action of cerebrosidase (CRS) on glycosphingolipids also by the action of ceramide 1-phosphate phosphatase (C1PP). Ceramide is further metabolized by ceramidase (CDase) to yield sphingosine, which is used as a substrate by SK1 and SK2 to generate S1P. S1P can be dephosphorylated by S1P phosphatases (S1PP) to generate sphingosine, or it can be irreversibly cleaved by S1P lyase into ethanolamine 1-phosphate and C 18 fatty aldehyde (hexadecenal). Ceramide is further metabolized to generate complex glucosyl and galactosyl-ceramide or glycolipids. Ceramide can be acted upon by sphingomyelin synthase to generate sphingomyelin or by ceramide kinase to generate ceramide 1-phosphate (C1P). C1P ceramide 1-phosphate, C1PP ceramide 1-phosphate phosphatase, CDase ceramidase, CerS ceramide synthase, CRS cerebrosidase, DES desaturase, GCS glucosyl ceramide synthase, S1P sphingosine 1-phosphate, S1PP S1P phosphatase, SK1 sphingosine kinase 1, SK2 sphingosine kinase 2, SM sphingomyelin, SMase sphingomyelinase, SPT serine palmitoyl transferase hexadecenal have been shown to promote MOMP (mitochondrial outer membrane permeabilization). Interestingly, S1P and hexadecenal have been shown to cooperate with BAK and BAX, respectively, to regulate MOMP and cellular responses to apoptosis (Chipuk et al. 2012). 3 Ceramide/S1P Rheostat in Cancer The fate of a cell is determined by the balance between ceramide and S1P signaling (not necessarily a quantitative ratio for the amount of lipids, but a biological/ metabolic balance between these two signaling arms of sphingolipids with

6 S.P. Selvam and B. Ogretmen Fig. 2 Ceramide-S1P rheostat in cancer and therapy. There exists a balance or rheostat in ceramide to S1P signaling in cancer. A shift towards ceramide accumulation leads to proapoptotic, autophagic, ER stress response, and anti-survival effects, whereas a dynamic shift towards S1P accumulation leads to pro-survival, anti-apoptotic, metastatic, and drug-resistant phenotypes. Potential therapeutic approaches will be to increase ceramide and decrease S1P in cancer cells by chemotherapy, radiation, monoclonal antibody, and other molecular approaches. ER endoplasmic reticulum, S1P sphingosine 1-phosphate opposing functions), which is often referred to as the ceramide/s1p rheostat (Fig. 2). There exists a dynamic balance between ceramide and S1P signaling, and when a shift towards ceramide is achieved by stress signaling such as radiation, heat, and chemotherapy treatment, this drives cells to undergo cell death and antiproliferation (Hannun and Obeid 2008). On the other hand, when the balance shifts towards S1P accumulation, cells exert pro-survival, anti-apoptosis, and/or chemoresistance (Ponnusamy et al. 2010). Increases in endogenous ceramide by chemotherapeutic agents, TNF-α, CD95, hypoxia, DNA damage, and heat stress can activate cell death pathways. Also, increases in ceramide via inhibiting ceramide metabolism or overexpressing CerS lead to cell death, in general. Moreover, overexpression of bacterial SMase, which generates ceramide by degradation of sphingomyelin, was shown to induce apoptosis (Meyers-Needham et al. 2012a). In contrast, inhibition of de novo ceramide generation by fumonisin B1 blocks ceramide-mediated cell death by chemotherapeutic drugs. Ceramide has various established intracellular targets such as PP1, PP2A, I2PP2A, cathepsin D, and protein kinase Cζ, which mediate its apoptotic/cell death functions (Fox et al. 2007; Heinrich et al. 2000; Ogretmen and Hannun 2004; Wang et al. 2005). Our laboratory identified telomerase to be a nuclear target of ceramide (exogenous C 6 -ceramide or C 18 -ceramide generated by CerS1) which decreased c-myc-mediated activation of htert promoter in lung cancer cells (Ogretmen et al. 2001). In fact, ceramide deacetylates Sp3 transcription factor